Abstract
We construct a generalized linear sigma model as an effective field theory (EFT) to describe nearly conformal gauge theories at low energies. The work is motivated by recent lattice studies of gauge theories near the conformal window, which have shown that the lightest flavor-singlet scalar state in the spectrum ($\sigma$) can be much lighter than the vector state ($\rho$) and nearly degenerate with the PNGBs ($\pi$) over a large range of quark masses. The EFT incorporates this feature. We highlight the crucial role played by the terms in the potential that explicitly break chiral symmetry. The explicit breaking can be large enough so that a limited set of additional terms in the potential can no longer be neglected, with the EFT still weakly coupled in this new range. The additional terms contribute importantly to the scalar and pion masses. In particular, they relax the inequality $M_{\sigma}^2 \ge 3 M_{\pi}^2$, allowing for consistency with current lattice data.
Highlights
In this paper we explore a linear sigma model as an effective field theory (EFT) description of gauge theories with approximate infrared conformal invariance.Asymptotically free gauge theories exhibit conformal behavior in the IR when the number of fermions Nf exceeds a critical value Ncf
An EFT is determined by the global symmetries of the system, a specification of the fields which transform according to some representation of the global symmetry group, and an ordering rule designating the relative importance of operators allowed by the symmetries
The potential VSB represents the effects of the quark mass within the EFT, including the explicit breaking of SULðNfÞ × SURðNfÞ chiral symmetry
Summary
In this paper we explore a linear sigma model as an effective field theory (EFT) description of gauge theories with approximate infrared conformal invariance. Recent work indicates that chiral perturbation theory does not describe lattice data of SU(3) gauge theory with Nf 1⁄4 8 fundamental flavors at currently accessible distances from the chiral limit [10,17,18] This is not surprising since the σ is similar in mass to the pions in the quark mass regime studied, and so a perturbatively implemented EFT which omits the σ resonance will not be an accurate description. One can extend chiral perturbation theory to include the σ by coupling a flavor-singlet scalar into the chiral Lagrangian in the most general way [19,20] These models have a large number of low-energy constants and are difficult to constrain with limited lattice data. In Appendix A, we describe the limit that allows the flavored scalars to be removed from the spectrum, and in Appendix B we discuss special considerations that apply to the case Nf ≤ 4
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